Optical fiber end-face preparation and connector assembly

ABSTRACT

A device for preparing an optical fiber for interconnection includes means for grasping the optical fiber at a first location along the optical fiber, means for scribing and breaking the optical fiber a first select distance from the first location, the means for scribing and breaking including guides for supporting and sliding the means for grasping along the guides in fixed relationship to the means for scribing and breaking, and means for polishing the optical fiber as broken, the means for polishing being connected to the means for breaking. The device also includes a polishing surface fixedly connected to the means for grasping. The polishing surface supports the means for grasping at a second select distance from the first location, the second select distance being shorter than the first select distance. The optical fiber is linearly moveable with respect to the polishing surface.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is related to U.S. patent application Ser. No. 08/801,058, filed on Feb. 14, 1997, of Sidney J. Berglund, et al., titled "Fiber Optic Connector Spring"; and U.S. patent application Ser. No. 08/577,740, filed on Dec. 22, 1995, of Barbara L. Birrell, et al., titled "Optical Fiber Connector Using Fiber Spring Force and Alignment Groove". These related applications are assigned to the assignee of the present invention and are hereby incorporated herein in their entirety by this reference thereto.

BACKGROUND OF THE INVENTION

The present invention generally relates to systems and methods for preparing and interconnecting communications lines and, more particularly, relates to optical fiber end-face preparation pucks and connector assembly tools and their methods.

In optical fiber networks, it is important that the optical fibers provide true and unimpeded optical transmission quality, even through connection points. The particular connector assemblies for the fibers are important in these regards. A variety of connectors and assembly tools and methods are conventional. Ferrules, such as metal or ceramic ferrules, for example, have been commonly employed elements for terminating optical fibers and providing or cooperating with connective structures for the fibers. Ferrules are typically cylindrical parts with internal passages for accepting an optical fiber end. The fiber end is retained in the ferrule, such as by an adhesive or close tolerance. Certain conventional connective assemblies maintain ferrules containing optical fiber ends in forced contact in order to optically connect the optical fiber end faces.

In lieu of ferrules, various other conventional optical fiber connectors and assembly tools are available. Examples of those connectors and assemblies include the designs shown in the related applications. Particularly, optical fiber end-face connections made in fiber-alignment grooves, such as V-shaped grooves, are disclosed in U.S. patent application Ser. No. 08/801,058, filed on Feb. 14, 1997, of Sidney J. Berglund, et al., titled "Fiber Optic Connector Spring" and U.S. patent application Ser. No. 08/577,740, filed on Dec. 22, 1995, of Barbara L. Birrell, et al., titled "Optical Fiber Connector Using Fiber Spring Force and Alignment Groove". The connectors having fiber-alignment grooves are typically less expensive than connectors requiring ferrules because the ferrules are fairly costly in comparison to the moldable parts making up the fiber-alignment grooved connectors.

In the case of all optical fiber connectors and connections, clean and precise end-face to end-face contact of connecting fibers is critical for superior transmissions. Thus, much efforts and assembly precautions are taken to provide desirable end-face contacts. Conventionally, optical fibers have been cleaved and the end-faces polished to provide desired contact. Various systems and methods of cleaving optical fibers and of polishing the end-faces thereof have been employed with varied results.

With respect to scribing and breaking optical fibers, for example, variations include the angle of the break, the degree of cutting or nicking to perform the scribing, the stresses applied to the fiber during the scribe and break, and others. As for choices in the polishing of end-faces of scribed and broken optical fibers, various pucks, holder elements, and polishing surfaces are possible. One conventional polishing technique has been to fix the fiber end with a ferrule and to hold and manipulate the ferrule to achieve polishing. In those techniques, the optical fiber end-face is moved via the ferrule across the polishing surface. The fiber end-face is polished away, as well as possibly portions of the ferrule. Another conventional technique has been to grip the fiber, either a ferruled or bare fiber, with a puck. The puck has been a solid, grippable piece with a flat surface. A passage within the puck is perpendicular to the flat surface and serves to accept the fiber (with ferrule, if applicable) to be polished. In the technique, small portions of the fiber protrude from the passage at the flat surface. The flat surface is passed across the polishing surface, thereby polishing away portions of the optical fiber end-face.

The typical polishing techniques present certain problems. A disadvantage in the case of ferruled fibers is that the polishing operation may cause both fiber and ferrule to be polished away. When using a typical polishing puck, a problem has been that the tolerance of the fiber within the puck presents breakage or splintering of the fiber as the flat surface is passed across the polishing surface. Furthermore, it has been difficult to obtain desired polishing results with bare fiber, such as bare fiber to be connected within fiber-alignment grooves, using the prior puck and other polishing systems.

It would be advantageous to not only provide improvements in polishing techniques, but also to provide more suitable systems and methods for in-the-field make-up of optical fiber connections wherein those improvements in polishing techniques are fully realized. Conventionally, ferrule fiber make-up is an involved process that must be undertaken in the manufacturing facility, rather than the field. It is sometimes advantageous, however, to be able to make a connection or other special fiber treatment in the field location. Certain of the conventional plug and socket connectors for optical fibers provide advantages in that field make-up of connections is more easily achieved. In any event of field operations, even with those plug and socket connectors, however, environmental contamination and conditions and lack of extensive facilities and equipment can limit connection assembly capabilities.

Therefore what is needed are systems and methods that ease make-up of optical fiber connections and that provide for improved and advantageous optical fiber end-face polishing to achieve superb optical fiber transmission characteristics with fiber connections. Embodiments of the present invention provide such systems and methods for optical fiber connection make-up with desirable end-face polishing and transmission capabilities. The invention, thus, improves field capabilities in assembling optical fiber connectors and also improves optical performance of optical fiber connections via those connector assemblies.

SUMMARY OF THE INVENTION

The embodiments of the present invention, accordingly, provide systems and methods for assembly of optical fiber connector sockets and for optical fiber polishing. The systems and methods provide advantages of easier and improved assembly of connector sockets in the field and otherwise and enhanced optical performance of the fiber connections because of the fiber end-face polish achievable.

To this end, an embodiment of the invention is a device for polishing an optical fiber at an end-face of the optical fiber. The device includes a body for retaining the optical fiber and a polishing surface attached to the body. The optical fiber protrudes through the polishing surface.

Another embodiment of the invention is a device for preparing an optical fiber for interconnection. The device comprises means for grasping the optical fiber at a first location along the optical fiber, means for scribing the optical fiber a first select distance from the first location, means for breaking the optical fiber at the first location, the means for scribing and the means for breaking including guides for supporting and sliding the means for grasping along the guides in fixed relationship to the means for scribing and the means for breaking, and means for polishing the optical fiber as broken, the means for polishing being connected to the means for breaking.

Yet another embodiment of the invention is a method of preparing an optical fiber for interconnection. The method includes steps of retaining the optical fiber within a polishing device from linear movement at a select location along the optical fiber, restraining the optical fiber to limited lateral movement, but allowing linear movement, at an end-face of the optical fiber, and sliding the end-face of the optical fiber across an abrasive surface. The optical fiber bows during engagement of the end-face with the abrasive surface.

Another embodiment of the invention is a method of preparing an optical fiber for interconnection. The method includes steps of grasping the optical fiber within a polishing device at a first location along the optical fiber, scribing the optical fiber at a select location along the optical fiber a select distance from the first location, breaking the optical fiber at the select location, and polishing the optical fiber so broken.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view of an optical fiber end-face preparation and connector assembly station, including a station base and a polishing puck, according to embodiments of the present invention.

FIG. 2 is a front perspective view of the station base of FIG. 1, showing the optical fiber scribing and cleaving area of the station base, according to embodiments of the present invention.

FIG. 3 is a perspective view of the polishing pluck of FIG. 1 in an open position, according to embodiments of the present invention.

FIG. 4 is a perspective view of the station base and the polishing puck of FIG. 1, wherein the polishing puck is positioned on a retaining ridge of the station base for optical fiber end-face preparation and connector assembly operations, according to embodiments of the present invention.

FIG. 5 is an exploded view of a conventional connector socket of the type having fiber-alignment grooves and a fiber holder (also shown in exploded view), which connector socket, including the fiber holder, are preparable using the optical fiber end-face preparation and connector assembly station of FIG. 1, according to embodiments of the present invention.

FIG. 6 is a perspective view of the polishing puck of FIG. 1 in open position and in use for assembling the fiber holder of the connector socket of FIG. 5, according to embodiments of the present invention.

FIG. 7 is a perspective view of the polishing puck of FIG. 6 in closed position and in use for assembling the fiber holder of the connector socket of FIG. 5, according to embodiments of the present invention.

FIG. 8 is a perspective view of the station base of FIG. 1 and the polishing puck of FIG. 7 in use for scribing and breaking optical fibers extending from the polishing puck and maintained by the fiber holder being assembled using the polishing puck, according to embodiments of the present invention.

FIGS. 9A-C are front views of the station base and the polishing puck of FIG. 8, wherein the polishing puck is located in several differing positions along a groove of the station base indicative of stages of the scribing and breaking process in preparation of the fiber holder of the connector socket of FIG. 5, according to embodiments of the present invention.

FIG. 10 is a perspective view of the station base and the polishing puck of FIG. 8 in closed position, wherein the polishing puck is being passed across a polishing surface of the station base in order to polish the end-faces of the optical fibers, according to embodiments of the present invention.

FIG. 11 is a perspective view of the station base and the polishing puck in open position, showing the fiber holder as assembled after scribing and breaking and polishing of the optical fibers extending from the polishing puck, and including a magnified view of the fiber holder and end-faces of the optical fibers after the scribing, breaking, and polishing, all according to embodiments of the present invention.

FIG. 12 is a perspective view of the station base and the polishing puck of FIG. 11 after the end-faces of the optical fibers have been polished and the polishing puck positioned on the retaining ridge of the station base and opened to reveal the fiber holder, wherein a microscope viewer is positioned with the polishing puck for viewing of the optical fiber end-faces, according to embodiments of the present invention.

FIG. 13 is an underside, perspective view of the microscope viewer shown in FIG. 12, according to embodiments of the present invention.

FIG. 14 is a side view of the microscope viewer of FIG. 13, showing the variable angular positioning possible in use, according to embodiments of the present invention.

FIG. 15 is a top, perspective view of the microscope viewer and the polishing puck of FIG. 12, showing relative positioning of the microscope viewer and the polishing puck during a typical optical fiber end-face inspection operation, according to embodiments of the present invention.

FIG. 16 is a perspective view of the station base and the polishing puck, showing a final stage of the assembly of the connector socket of FIG. 5, as assembled from the fiber holder prepared using the optical fiber end-face preparation and connector assembly station, including the station base and the polishing puck, as shown in FIGS. 1-4, 6-11, and 12-15, according to embodiments of the present invention.

FIG. 17 is a close-up perspective view of the final stage of the assembly of the connector socket shown in FIG. 16, in position with the polishing puck, according to embodiments of the present invention.

FIG. 18 is a flow diagram of a process of assembling the final stage connector socket of FIG. 5, using the optical fiber end-face preparation and connector assembly station of FIG. 1, and shows the station base the polishing puck of the assembly station at the various steps of the process.

FIG. 19 is a perspective view of an alternative station base for use with the polishing puck like that of FIG. 8, which alternative station base provides a linear alignment for achieving both scribing and breaking of optical fibers extending from the polishing puck and polishing of the end-faces of the optical fibers after the scribing and breaking, according to embodiments of the present invention.

FIGS. 20A-H are perspective views of a first alternative polishing puck, in various opened and closed views, at various stages of assembly of the final stage connector socket of FIG. 5, according to embodiments of the present invention.

FIGS. 21A-F are perspective views of a second alternative polishing puck, in various opened and closed views, at various stages of assembly of the final stage connector socket of FIG. 5, according to embodiments of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

Reference is hereby made to the parent and related applications for details of optical fiber connectors, particularly connector sockets, wherein optical fiber connections are made in fiber-alignment grooves. Because details are given in those applications of the connectors, including the connector sockets, the connectors are not discussed herein in detail. The discussion herein focuses primarily on embodiments of systems and methods for optical fiber end-face preparation and connector socket assembly.

Referring to FIG. 1, an optical fiber end-face preparation and connector assembly station 2 includes a station base 4 and a polishing puck 6. The station base 4 is generally rectangular with a forward planar end 4a and a rearward curved end 4b. Along one side 4c, the station base 4 is formed with a puck storage chamber 8 in which may be stored the polishing puck 6 when not in use preparing optical fiber end-faces and connector socket assemblies. A groove 10 is formed from the forward planar end 4a continuing toward the rearward curved end 4b, but stopping about mid-way through the station base 4. A depth of the groove 10 is on the order of over half a height of the station base 4. The groove 10 opens to a top of the station base 4. At the rearward curved end 4b and atop the station base 4, a polishing surface 12 is positioned. The polishing surface 12 is, for example, circular. Atop the station base 4 at a location not occupied by the groove 10 and the polishing surface 12 is formed a retaining ridge 14. The retaining ridge 14 attaches with the polishing puck 6 to retain the polishing puck 6 in desirable position when preparing optical fiber end-faces and assembling connector sockets.

Referring to FIG. 2, the groove 10 of the station base 4 includes guide tracks 16 on each side of the groove 10 near the top of the station base 4. The guide tracks 16 are suitable to mate with portions of the polishing puck 6 (shown in FIG. 1) to allow sliding movement of the polishing puck 6 in scribing and breaking operations, as will be later discussed. Along a wall of the groove 10 approaching the bottom of the groove 10, a bender portion 18 is located. The bender portion 18 includes a rounded and angled edge beginning near the forward planar end 4a of the station base 4. As the bender portion 18 runs along the groove 10 extending toward the rearward curved end 4b, the bender portion 18 initially extends ever farther across the groove 10. The bender portion 18 does not, however, ever extend the entire width of the groove 10 and reaches a set width on the order of half the width of the groove 10 and continues at that set width in rearward portions of the groove 10.

In addition to the bender portion 18, a scribe 20 is positioned in the groove 10. The scribe 20 is an appendage extending from the wall of the groove 10 from which the bender portion 18 extends, beginning about halfway down the wall of the cleaving groove 18, and is angled upwardly. At about the location of the plane formed by the lower edges of the guide tracks 16, the scribe 20 ends in a generally sharp-angled edge 20a. The sharp-angled edge 20a is selectively situated with relation to the positioning of the polishing puck 6 when positioned in the guide tracks 16, so that the sharp-angled edge 20a contacts circumferences of optical fibers retained by the polishing puck 6 during end-face preparation and connector assembly operations, as will later be described in detail.

In effect, the bender portion 18 causes optical fibers retained by the polishing puck 6 to progressively bend farther and farther away from the wall of the groove 10 on which the scribe 20 and bender portion 18 are attached as the polishing puck 6 is moved in the guide tracks 16 from the forward planar end 4a toward the rearward curved end 4b. As a select bend of the optical fibers is obtained, desirably stressing the optical fibers, the optical fibers are nicked at their circumference near the polishing puck 6 by the sharp-angled edge 20a of the scribe 20. The nick, coupled with additional bending of the optical fibers as the polishing puck 6 continues to progress rearward and the optical fibers follow the bender portion 18, creates a desirable and select scribe and break of the optical fibers.

Referring to FIG. 3, the polishing puck 6 includes a base 30 and a top 32. The base 30 and the top 32 are connected by a hinge 34. The hinge 34 allows the top 32 to be positioned fully open with respect to the base 30, as shown in FIG. 3, and to be positioned closed, in which the top 32 is in full contact with and over the base 30.

The base 30 includes fiber lead-in grooves 36, for example, two such grooves, in a surface of the base 30. The fiber lead-in grooves 36 extend the length of the base 30, however, the grooves 36 are interrupted in a mid-portion of the base by a socket fiber holder nest 38. The socket fiber holder nest 38 is a generally square cut-out in the surface of the base 30, sufficient to accommodate a socket fiber holder (such as that shown in the related applications and in FIG. 5 hereof). It is of note that the fiber lead-in grooves 36 extend on each side of the socket fiber holder nest 38 and intersect with it. The base also includes a first polishing surface portion 40 positioned adjacent the fiber lead-in grooves 36 at an end of the base 30. Tips 40a of the first polishing surface portion are narrow, grooved (e.g., v-shaped and/or u-shaped grooves) surfaces sufficient for resting therein optical fibers which pass through the fiber lead-in grooves 36 at the end of the base 30. The base 30 is also equipped with viewer mounting holes 41 at the end near the first polishing surface portion 40 and a clasp extension 42 along an edge opposite the hinge 34.

At the hinge 34, the top 32 hingedly mates with the base 30. The top 32 includes a cut-out 44 that extends along almost the entire length of the top 32 in a mid-section thereof, on a side of the top 32 which contacts the base 30 when the top 32 is closed against the base 30. At a forward location in the cut-out 44 which matches with the location of the socket fiber holder nest 38 when the top 32 is closed against the base 30, is formed an actuator pad 46. The actuator pad 46 protrudes outward from within the cut-out 44 sufficient distance to press-fit a socket fiber holder (shown in the related applications and in FIG. 5) assembled in the socket fiber holder nest 38 and is, for example, half-sphere shaped. The top 32 further includes clasp fittings 48 for mating with the clasp extension 42 and securing the top 32 atop the base 30 when the top 32 is closed against the base 30. A second polishing surface portion 50 is affixed at an end of the top 32. At that end, the second polishing surface portion 50 is positioned relative to ridges 52 between the second polishing surface portion 50 and the cut-out 44. The ridges 52 mate with the fiber lead-in grooves 36 of the base 30 when the top 32 is closed against the base 30 and provide tolerance for maintenance of optical fibers within the fiber lead-in grooves 36. The second polishing surface portion 50 includes notches 50a which mate with the tips 40a of the first polishing surface portion 40 when the top 32 is closed against the base 30. At the apex of the tips 40a and the extent of the notches 50a when the first polishing surface portion 40 and the second polishing surface portion 50 are mated, sufficient tolerance between the first polishing surface portion 40 and the second polishing surface portion 50 remains to accommodate optical fibers positioned in the fiber lead-in grooves 36 and passing through the polishing puck 6. The tolerance provided to so accommodate those optical fibers is herein referred to as the "polishing surface holes", and the first polishing surface portion 40 and the second polishing surface portion 50 when mated are sometimes referred to herein as the "polishing surface 40/50".

Referring to FIG. 4, the polishing puck 6 is closed so that the top 32 contacts the bottom 30. The polishing puck 6, in that closed orientation, is positioned on the retaining ridge 14 (shown in FIGS. 1 and 2) of the station base 4. As so positioned, the polishing puck 6 is maintained for optical fiber end-face preparation and connector socket assembly operations. Although not shown in detail in the Figures, the polishing puck 6 includes a groove on an underside of the base 30. That groove mates with the retaining ridge 14 of the station base 4 to secure the polishing puck 6 with the station base 4 during those preparation and assembly operations.

Referring to FIG. 5, a connector socket 114 of a conventional type which is assemblable using the optical fiber end-face preparation and connector assembly station 2 is shown. The connector socket 114 is more fully discussed and described in the related U.S. patent application Ser. No. 08/801,058, filed on Feb. 14, 1997, of Sidney J. Berglund, et al., titled "Fiber Optic Connector Spring". The connector socket 114 is briefly described here as well, however, because an understanding of the connector socket 114, and particularly a fiber holder 172 thereof, is helpful to an understanding of the features, use, and benefits of the optical fiber end-face preparation and connector assembly station 2.

The connector socket 114 includes a housing 170, the fiber holder 172, and a bottom piece 187. The base 173 has hooks 188 and passageways through opposing walls for passage of optical fibers 178 and 180 therethrough. Internally to the base 173 are several projections 173a extending from the base 173. The projections 173a are selectively spaced to accommodate clamping plates 181. The clamping plates 181 are each formed of a malleable material, for example, a malleable aluminum metal, in a somewhat U-shape. The clamping plates 181 each hold respective ones of the optical fibers 178 and 180 within the U-shape. Because the clamping plates 181 are malleable, they may be crimped (for example, by closing of the polishing puck 6 which effects pressing engagement of the actuator pad 46 with the fiber holder 172 assembly, as hereinafter described) to engage the respective ones of the optical fibers 178 and 180. When so crimped, the clamping plates 181, when located between respective sets of the projections 173a, retain the optical fibers 178 and 180 with the base 173. A cover 179 of the fiber holder 172 includes inserts which fit notches of the base 173 to retain the cover 179 on the base 173 when the inserts and notches are engaged. In certain embodiments, pressing of the cover 179 onto the base 173 to engage the inserts and notches may serve to cause the crimping of the clamping plates 181 necessary to retain the optical fibers 178 and 180.

The fiber holder 172, with the base 173, the clamping plates 181 with the optical fibers 178 and 180 therein, and the cover 179 connected together as described, attaches to posts 171 of the housing 170 via the hooks 188. The hooks 188 snap onto the posts 171, and the fiber holder 172 pivots into place against the underside of the housing 170.

With the fiber holder 172 in place in that manner, outer hooks 189 of the bottom piece 187 snap onto the posts 171 external to the hooks 188. The bottom piece 187, as so engaged by the outer hooks 189 with the posts 171, pivots into place against the housing 170. The bottom piece 187 has upward extensions 252. These upward extensions have holes 254. The housing 170 includes notches 250. The holes 254 mate with the notches 250 when the bottom piece 187 is pressed to the housing 170. When the holes 254 and the notches 250 are so mated, the housing 170, the fiber holder 172, and the bottom piece 187 remain engaged, forming the connector socket 114.

Referring to FIG. 6, polishing puck 6 in open position has the fiber holder 172 assembly located in the socket fiber holder nest 38. The fiber holder 172 includes components just described. Optical fibers 178 and 180 extend through the fiber holder 172 and reside in respective ones of the fiber lead-in grooves 36. The optical fibers 178 and 180 extend beyond the grooves 36 and rest on respective ones of the tips 40a of the first polishing surface portion 40. It is to be understood that the fiber holder 172 shown in FIG. 6 is not yet assembled so that the clamping plates 181 are not crimped to hold the optical fibers 178 and 180, and the cover 179, the base 173, and the clamping plates 181 are not engaged as a single unit. Rather, the optical fibers 178 and 180 merely reside within the clamping plates 181, the clamping plates 181 are located between respective sets of projections 173a of the base 173, and the cover 179 sits atop the base 173 but is not engaged via the inserts and notches.

Referring to FIGS. 6 and 7, in conjunction, the polishing puck 6 is in closed position for actuation of assembly of the fiber holder 172 (shown in FIG. 6). The fiber holder 172 continues to reside in the socket fiber holder nest 38, however, the fiber holder 172 has been actuated by force of the actuator pad 46 against the cover 179. That force is exerted by the actuator pad 46 when the top 32 of the polishing puck 6 is closed against the base 30. On such actuation of the fiber holder 172, the clamping plates 181 (shown in FIG. 5) are clamped against the respective optical fibers 178 and 180, the cover 179 and the base 173 are joined by engagement of the inserts and notches thereof, and the clamping plates 181 are fixed within the fiber holder 172 thereby holding the optical fibers 178 and 180 via the fiber holder 172. The optical fibers 178 and 180 extend from the fiber holder 172 through polishing surface holes 54 of the polishing surface 40/50.

Referring to FIG. 8, the polishing puck 6 in closed position, for example, having the fiber holder 172 actuated as a unitary piece maintained within the socket fiber holder nest 38 between the base 30 and the top 32, is positioned in the guide tracks 16 of the station base 4. Edges of the polishing surface 40/50 fit within the guide tracks 16 and allow the polishing puck 6 to slide within the guide tracks 16 along the length of the groove 10 of the station base 4. The arrow A in FIG. 8 indicates the direction along the groove 10 in which the polishing puck 6 is moved in order to scribe and break the optical fibers 178 and 180 to continue end-face and connector assembly preparation.

Referring to FIGS. 9A-C, in conjunction with FIG. 8, the polishing puck 6 is positioned in several different orientations with the station base 4 during a scribing and breaking operation. In FIG. 9A, the polishing puck 6 is initially inserted into the groove 10 with edges of the polishing surface 40/50 located in the guide tracks 16. As so initially inserted into the groove 10, the optical fibers 178 and 180 (only optical fiber 178 is shown, although it is to be understood that the optical fiber 180 is located directly in line with the optical fiber 178 and so is not seen in the end views of FIGS. 9A-C) extend substantially straight downward within the groove 10. As the polishing puck 6 is slid along the guide tracks 16 in the direction of arrow A, the optical fiber 178 contacts the bender portion 18, as shown in FIG. 9B. The optical fiber 178 extending from the polishing puck 6 is bent by the bender portion 18. As shown in FIG. 9C, as the polishing puck 6 continues in progression along the guide tracks 16 in the direction of arrow A, the sharp-angled edge 20a of the scribe 20 contacts the optical fiber 178 as it extends from the polishing surface 40/50. In so contacting the optical fiber 178, the sharp-angled edge 20a introduces a flaw in the circumference of the optical fiber 178 under stress from the bend caused by the bender portion 18. The stress of the bend, coupled with the flaw introduced by the sharp-angled edge 20a of the scribe 20, breaks the optical fiber 178 as it just extends through the polishing surface 40/50, for example, the optical fiber 178 protrudes about 10 μm to about 250 μm (i.e., about twice the fiber diameter), from the polishing surface 40/50.

It is appropriate at this point to briefly discuss optical fiber end-face characteristics and preferences for effective optical fiber connections in order to more fully appreciate the advantages of end-face preparation and connector assembly using the embodiments of the optical fiber end-face preparation and connector assembly station 2 of the present invention. In general, there are at least four parameters important to optical quality of optical fiber connections. Those parameters are the optical fiber end-face angle, planarity, surface quality, and location. End-face angle is important for proper contact of optical fiber end-face to optical fiber end-face or optical device connections. Planarity refers to the planar or non-planar shape of the optical fiber end-face. Consistent planarity, whether or not in fact planar, between optical fiber end-face to optical fiber end-face or device connections is important in order to achieve desirable transmission of light across the connections. End-face surface quality refers to the particular characteristics of the glass surface of the optical fiber end-face. A smooth, rather than rough, end-face surface is desired for suitable connections. Optical fiber end-faces are, therefore, commonly polished to achieve smooth end-face surfaces. Another important parameter is end-face location which refers to the distance from the center of the core of an optical fiber to a reference, for example, the distance the optical fiber end-face extends from the fiber holder 172 in the case of the connector socket 114 of FIG. 5. The end-face location is sometimes referred to in the art as "cleave length" in the case of splicing where a length of bare glass is prepared by stripping the fiber coating to the fiber end-face. End-face location is preferably consistent for each of multiple fiber joints where the fiber joints are made with respect to the same reference because of requirements of limited tolerances of most of the typical optical fiber connectors. The embodiments of the optical fiber end-face preparation and connector assembly station 2 of the present invention allow for consistency and precision in the parameters and, thus, provide significant advantages.

Referring to FIG. 10, with respect to polishing the optical fibers 178 and 180 once broken, the station base 4 includes the polishing surface 12. The polishing surface 12 is a circular area covered by a lapping film. The polishing surface 12 is located at the aft end of the groove 10. The guide tracks 16 continue along the groove 10 to the aft end thereof and end at the polishing surface 12. The guide tracks 16 feed onto the polishing surface 12, so that the polishing puck 6, when moved along the guide tracks 16 to the aft end, lands on the polishing surface 12 after passing from the guide tracks 16. The polishing puck 6 is oriented with the polishing surface 40/50 of the polishing puck 6 generally planarity aligned with the polishing surface 12 of the station base 4. The polishing puck 6 is moveable across the lapping film of the polishing surface 12 in that orientation.

Polishing of optical fiber end-faces is conventionally accomplished by skilled craftsmen who by sense of subjective "feel", based on experience, determine when the end-faces are satisfactorily polished. Polishing via the polishing surface 12 and the polishing puck 6 can also be achieved by subjective determination of the craftsman. However, because of the particular design of the optical fiber end-face preparation and connector assembly station 2, the polishing process may be somewhat (or even possibly entirely) rendered non-objective. For example, the optical fiber scribe and break operations with the station base 4 and the polishing puck 6 achieve substantially uniform scribe and break results with respect to the four parameters previously discussed in each scribe and break operation. Because scribe and break results are uniform with the optical fiber end-face preparation and connector assembly station 2, procedures can be established for polishing to achieve substantially consistent polishing results, without reliance on subjectivity of the craftsman. Likewise, polishing results may be optimized and consistently maintained by following the same polishing procedures with the polishing surface 12 in each instance, such as particular polishing patterns, numbers of strokes, and pre-load. Patterns can, for example, be circular, figure eights, linear or other. With each pattern, there is an optimal number of "strokes" to achieve desired polishing results given a particular scribe and break. Pre-load refers to the force that is applied during the polishing process that forces the optical fiber end-face against the lapping film. Pre-load is also consistent among each polishing operation with the optical fiber end-face preparation and connector assembly station 2.

Particularly as to pre-load of the optical fiber being polished using the optical fiber end-face preparation and connector assembly station 2, the pre-load results from the length of optical fiber which protrudes from the polishing surface 40/50 of the polishing puck 6. The polishing puck 6 does not hold the optical fiber rigid at the polishing surface 40/50 because of clearance between the polishing surface 40 and the polishing surface 50 and the optical fiber located there between. Instead, the polishing puck 6 only holds the optical fiber rigid at the socket fiber holder nest 38 (shown in FIG. 6) via the fiber holder 172 (shown in FIG. 6). This allows the optical fiber to bow in the length between the fiber holder 172 and the optical fiber end-face. The stresses resulting from this bow of the optical fiber tend to push the end-face into the abrasive surface of the lapping film with a relatively consistent force. As the polishing puck 6 is maneuvered over the polishing surface 12, glass is removed from the end-face of the optical fiber. As the glass is removed from the end-face during polishing, the length of the optical fiber from the fiber holder 172 to the end-face is shortened, and the bow lessens until the optical fiber straightens when the fiber no longer protrudes from the polishing surface 40/50 of the polishing puck 6 (i.e., the optical fiber end-face is in the same plane as the polishing surface 40/50 adjacent the polishing surface 12) and bow stress is relieved.

Of course, variations in polishing are possible. For example, it is not necessary that polishing be continued until the optical fiber end-face no longer protrudes from the polishing surface 40/50 so as to be in a bow-stress free state. Further, the optical fiber end-face angle tolerance is determined by the dimensions of the polishing surface hole 54. The aspect ratio of the hole 54 is the ratio of the length of the hole 54 (i.e., the thickness of polishing surface 40/50) to the lateral dimension (i.e., the diameter if the hole 54 is circular) of the hole 54. A high value for the aspect ratio provides a more exact and consistent end-face angle from polishing. In another possible configuration, the optical fiber is held at the polishing surface 40/50 by a low durometer elastomer, for example, such an elastomer filling the clearance between the optical fiber and the polishing surface hole 54. This limits the possible movement of the optical fiber within the polishing surface hole 54. Stretching of the elastomer when the optical fiber is passed across the lapping film provides the contact pressure for the optical fiber against the abrasive to achieve the polishing. Even further, the polishing surface 12 may be moved with respect to the polishing surface 40/50, or both surfaces 12 and 40/50 may be moved to achieve relative movement.

Referring to FIG. 11, the polishing puck 6 is located on the retaining ridge 14 of the station base 4 and in opened position in order to allow examination of the polished end-faces of the optical fibers 178 and 180 and cleaning. In particular in the magnified view of FIG. 11, the optical fibers 178 and 180 are shown as scribed, broken and polished at the end-faces. The end-faces of the optical fibers 178 and 180 are seen to extend to the plane of the polishing surface 40 at the tips 40a. It can be understood that the optical fibers 178 and 180, including their end-faces, can be examined and cleaned because of the arrangement. Of note in FIG. 11 are the viewer mounting holes 41.

Referring to FIGS. 11-13, in conjunction, a microscope viewer 200 is mounted in the viewer mounting holes 41 of the polishing puck 6. The microscope viewer 200 is, for example, a 100X microscope. The microscope viewer 200 includes a microscope housing 202 fitted with a microscope foot 204. The microscope foot 204 is, for example, a clear plastic that allows passage of light. An integral light 206 (not shown in detail) is contained within the microscope foot 204 and directed at the focal point of the microscope viewer 200. A microscope objective 208 is located at an end 202a of the microscope housing 202. The end 202a of the microscope housing 202 is fitted with a viewer adapter base 210. The viewer adapter base 210 includes a pivot hole 210a which mates with the microscope housing 202 in such manner that the microscope housing 202 may be turned side-to-side, for example, in order to view multiple optical fibers in side-by-side relationship, without removing the microscope viewer 200 from the viewer mounting holes 41. A pivot hole 210b of the viewer adapter base 210 hinges with a post bracket 212. Because of the pivot hole 210b, the viewer adapter base 210 pivots vertically (in the Figures) with respect to the post bracket 212. The post bracket 212 includes posts 214 which are fixed in extension from the post bracket 212. The posts 214 fit within the viewer mounting holes 41 to allow mounting of the microscope viewer 200 on the polishing puck 6.

Referring to FIG. 14, when the microscope viewer 200 is so mounted on the polishing puck 6, the microscope housing 202 is movable with respect to the polishing puck 6. A line of sight 208a of the microscope viewer 200 is adjustable over the angle ξ. The adjustment over the angle ξ is possible because of the hinged relation at the pivot hole 210b of the viewer adapter base 210 with the post bracket 212.

Referring to FIG. 15, an eye piece 215 of the microscope viewer 200 is located at an end 202b of the microscope housing 202 opposite the viewer adapter base 210. The eye piece 215 allows viewing through the microscope viewer 200 of the optical fibers 178 and 180 at tips 40a of the polishing surface 40 (shown in FIG. 11) of the polishing puck 6.

Referring to FIGS. 16 and 17, in conjunction, the fiber holder 172 (shown in FIG. 11) is fitted with the housing 170 of the connector socket 114 (shown in FIG. 5) while the fiber holder 172 remains in the socket fiber holder nest 38 of the polishing puck 6. The posts 171 of the housing 170 are snapped into the hooks 188 of the fiber holder 172. The housing 170 and the fiber holder 172 assembly is then removable from the polishing puck 6 and the bottom piece 187 fixable therewith to complete the connector socket 114.

Referring to FIG. 18, in operation, the optical fiber end-face preparation and connector assembly station 2, including the station base 4 and the polishing puck 6, provides for preparation and completion of optical fiber end-faces and connector socket assemblies. A process 300 for such preparation and completion proceeds as follows. In a step 302, the polishing puck 6 is initially stored in the puck storage chamber 8 of the station base 4. In a step 304, the polishing puck 6 is removed from the storage chamber 8 and mounted on the retaining ridge 14 (shown in FIGS. 1 and 2) of the station base 4. The polishing puck 6 is also opened by rotating the top 32 from the base 30 to reveal the socket fiber holder nest 38.

In a step 306, a fiber holder 172 (shown in FIG. 6) assembly is located in the socket fiber holder nest 38. The optical fibers 178 and 180 are extended through the fiber holder 172 and positioned to reside in respective ones of the fiber lead-in grooves 36 in the base 30 of the polishing puck 6. The optical fibers 178 and 180 extend beyond the polishing surface 40 of the polishing puck 6. The fiber holder 172 in the step 306 is not yet engaged or actuated as a single unit. Instead, the component parts of the fiber holder 172 are merely located in the socket fiber holder nest 38 with the optical fibers 178 and 180, and oriented for engagement on actuation.

In a step 308, the top 32 of the polishing puck 6 is closed against the base 30 of the polishing puck 6. By so closing the top 32, the top 32, via the actuator pad 46 (shown in FIGS. 6 and 7), actuates the fiber holder 172 contained within the socket fiber holder nest 38 to engage the fiber holder 172 as a single unit. In the step 308, the clamping plates 181 clamp the optical fibers 178 and 180 and the cover 179 engages the base 173, so that the optical fibers 178 and 180 are fixed with the fiber holder 172.

In a step 310, the polishing puck 6 is removed from the retaining ridge 14 of the station base 4 and the polishing surface 40/50 of the polishing puck 6 is engaged with the guide tracks 16 of the groove 10. The polishing puck 6 as so positioned is slid in the direction of arrow A along the guide tracks 16 of the groove 10. As the polishing puck 6 is so slid, the optical fibers 178 and 180 contact the bender portion 18 (shown in FIG. 9B) and are bent. As the polishing puck 6 continues its slide along the guide tracks 16, the sharp-angled edge 20a (shown in FIG. 9B) of the scribe 20 (shown in FIG. 9B) contacts at the circumferences of the optical fibers 178 and 180 and introduces a flaw into the outer surface of each of the optical fibers 178 and 180. The stress of the bends, coupled with the introduction of the flaws, breaks the optical fibers 178 and 180 as they just extend through the polishing surface 40/50 of the polishing puck 6. For example, the optical fibers 178 and 180 after scribing and breaking protrude from about 10 μm to about 250 μm (or as otherwise desired) from the polishing surface 40/50.

In a step 312, the polishing puck 6 slides out of the guide tracks 16 onto the polishing surface 12 of the station base 4. The polishing surface 12 is, for example, a lapping film or other abrasive surface. The grit of the polishing surface 12 is chosen according to the desired polishing results, as is conventional. In the step 312, the polishing puck 6 is moved in patterns, as previously mentioned, across the polishing surface 12. Because the optical fibers 178 and 180 protrude from the polishing surface 40/50 of the polishing puck 6, the end-faces of the optical fibers 178 and 180 are polished via the movement of the polishing puck 6. As previously described, the pre-load for the polishing is achieved, for example, by bowing of the optical fibers 178 and 180 over the length of the fibers 178 and 180 from the fiber holder 172 to the end-faces. This pre-load can achieve uniform and consistent polishing results among multiple polishing efforts.

In a step 314, the polishing puck 6 is again mounted on the retaining ridge 14 of the station base 4 and the top 32 opened from the base 30. With the top 32 opened in this manner, the optical fibers 178 and 180 may be cleaned, for example, by manual adhesive or liquid solvent cleaners, such as HFE. To view the optical fibers 178 and 180 at their polished end-faces, the microscope viewer 200 is mounted on the polishing puck 6. The microscope viewer 200 is rotatable laterally and vertically to desirably view the optical fibers 178 and 180. After inspection, the microscope viewer 200 is removed from its mounting with the polishing puck 6.

In a step 316, the fiber holder 172 maintained in the socket fiber holder nest 38 is fitted with the housing 170. The posts 171 of the housing 170 are locked with the hooks 188 of the fiber holder 172, and the housing is pressed against the fiber holder 172. This locates the end-faces of the optical fibers 178 and 180 retained by the fiber holder 172 in fiber-alignment grooves of the housing 170. The fiber holder 172 and housing 170 assembly is then removed from the socket fiber holder nest 38 and fitted with the bottom piece 187 to complete the connector socket 114.

Referring to FIG. 19, an alternative station base 404 provides a linear polishing surface 412 at the end of a cleaving groove 410. The cleaving groove 410 includes a bender portion 418 and a scribe (not shown). Guide tracks 416 are provided at the top edges of the cleaving groove 410 for guiding the polishing puck 6. The linear polishing surface 412 is located at the end of the cleaving groove 410 in such manner that cleaving and polishing of optical fibers (not shown) maintained by a fiber holder (not shown) contained in the polishing puck 6 is accomplishable in a single-pass operation. Alternatively, the polishing puck 6 may be passed across the polishing surface 412 several times, as desired. Furthermore, the lapping film may be indexed so that it is replaced with each polishing operation or so that it is graded in such manner as to maintain relatively constant abrasive characteristics.

Referring to FIGS. 20A-20H, in conjunction, a first alternative polishing puck 506 includes a one-piece polishing surface 540. The polishing surface 540 includes fiber holes 554. The polishing surface 540 is attached to an arm 550. The arm 550 is hinged by a hinge 534 with a top 532 and a base 530. The top 532 includes a cut-out 544 in which is located an actuator pad 546. The base 530 includes a socket fiber holder nest 538 which connects with fiber lead-in grooves 536 of the base 530. Other than the arm 550 and the one-piece polishing surface 540, the first alternative polishing puck 506 is otherwise substantially similar to the polishing puck 6, previously described.

In operation, the first alternative polishing puck 506 may be retained, for example, on the retaining ridge 14 of the station base 4 (shown in FIGS. 1 and 2). As shown in FIG. 20A, the top 532 is rotated from the base 530 to open the first alternative polishing puck 506. The arm 550 is also rotated from the base 530. This exposes the fiber lead-in grooves 536 and the socket fiber holder nest 538.

In FIG. 20B, the fiber holder 172, in an unactuated condition, is placed into the socket fiber holder nest 538 and the arm 540 is closed against the base 530. As shown in FIG. 20C, the optical fibers 178 and 180 are then fed through the fiber lead-in grooves 536, through the fiber holder 172, and through the fiber holes 554 of the one-piece polishing surface 540.

In FIG. 20D, the top 532 is closed against the base 530. This actuates the fiber holder 172 to engage the optical fibers 178 and 180. The first alternative polishing puck 506 is then employed in a cleaving and polishing process to cause the optical fibers 178 and 180 to terminate in end-faces substantially planar with the one-piece polishing surface 540.

In FIG. 20E, the top 532 is opened to reveal the fiber holder 172 and the optical fibers 178 and 180. The optical fibers 178 and 180 remain positioned within the fiber holes 554. In FIG. 20F, however, the arm 550 is moved a small distance laterally away from the base 530 and is then rotated from the base 530 and, in the process of such rotation, the optical fibers 178 and 180 dislocate from the fiber holes 554. The end-faces of the optical fibers 178 and 180 extend beyond the base 530. Alternatively, although not detailed in the Figures, the polishing surface 540 may be hinged to the base 530, for example, towards the bottom of the polishing surface 540. In such embodiment, the polishing surface 540 is swung downward via the hinge to dislocate the optical fibers 178 and 180 from the fiber holes 554 and to allow access to the optical fibers 178 and 180.

In FIG. 20G, the microscope viewer 200 is mounted on the base 530 for inspection of the optical fibers 178 and 180. Once inspection is completed, the microscope viewer 200 is dismounted. In FIG. 20H, the fiber holder 172 is fitted with the housing 170 by the posts 171 and the hooks 188.

Referring to FIGS. 21A-21F, in conjunction, a second alternative polishing puck 606 includes a polishing surface 640. The polishing surface 640 includes fiber holes 654 and a viewing gap 656. The polishing surface 640 is attached to a base 630. A top 632 is connected with the base 630 by a hinge 634. The top 632 includes a cut-out 644 in which is located an actuator pad 646. The base 630 includes a socket fiber holder nest 638. Fiber grooves 636 of the base 630 extend between the socket fiber holder nest 638 and the polishing surface 640. The socket fiber holder nest 638 also connects with a cut-out 637 of the base 630. Although shown as the cut-out 644 in the Figures, the cut-out 644 may alternatively be fiber lead-in grooves 536, such as those shown in FIGS. 20A-G. Other than the polishing surface 640 having fiber holes 654 and the gap 656, the second alternative polishing puck 606 is otherwise substantially similar to the polishing puck 6, previously described.

In operation, the first alternative polishing puck 606 may be retained, for example, on the retaining ridge 14 of the station base 4 (shown in FIGS. 1 and 2). As shown in FIG. 21A, the top 632 is rotated from the base 630 to open the second alternative polishing puck 606. This exposes the fiber grooves 636, the cut-out 637, and the socket fiber holder nest 638.

In FIG. 21B, the fiber holder 172, in an unactuated condition, is placed into the socket fiber holder nest 638. As shown in FIG. 21C, the optical fibers 178 and 180 are then fed through the cut-out 637, the fiber holder 172, the fiber grooves 636, and the fiber holes 654 of the polishing surface 640.

In FIG. 21D, the top 632 is closed against the base 630. This actuates the fiber holder 172 to engage the optical fibers 178 and 180. The second alternative polishing puck 606 is then employed in a cleaving and polishing process to cause the optical fibers 178 and 180 to terminate in end-faces substantially planar with the polishing surface 640.

In FIG. 21E, the top 632 is opened to reveal the fiber holder 172 and the optical fibers 178 and 180. The optical fibers 178 and 180 remain positioned within the fiber holes 654. In FIG. 21F, the fiber holder 172 is fitted with the housing 170 by the posts 171 and the hooks 188.

Although illustrative embodiments of the invention have been shown and described, a wide range of modification, change, and substitution is contemplated in the foregoing disclosure and, in some instances, some features of the present invention may be employed without a corresponding use of the other features. Accordingly, it is appropriate that the appended claims be construed broadly and in a manner consistent with the scope of the invention. 

What is claimed is:
 1. An optical fiber end-face preparation device, comprising:a station base having an open groove therein said groove in said station base having guide tracks on each side of said groove near the top of said station base and a scribe and a fiber bender extending from a wall of said groove a polishing puck releasably attachable to said station base, said puck having a body for retaining an optical fiber and a planar surface attached to an end of the body; and said planar surface of said puck having a hole through which said optical fiber protrudes and edges that fit within said guide tracks of said groove in said station base.
 2. The device of claim 1, wherein said station base includes a polishing surface atop said station base adjacent said groove.
 3. The device of claim 1, wherein said polishing puck body comprises a puck base and a top connected to said puck base by a hinge, said hinge allowing said top to be closed over said puck base and alternately opened away from said puck base.
 4. The device of claim 3, wherein said puck base includes at least one fiber lead-in groove and a nest for accommodating a fiber holder.
 5. The device of claim 4, wherein said top of said polishing puck includes an actuator pad positioned to press against said fiber holder in said nest when said top is closed over said puck base.
 6. The device of claim 1, wherein said polishing puck includes means for mounting a microscopic viewer for viewing the optical fiber end-face.
 7. A method of preparing an optical fiber end-face for interconnection, comprising the steps of:providing a polishing puck having a body and a planar surface attached to an end of the body; retaining the optical fiber within the puck body such that an end of the fiber extends through a hole in the planar surface; guiding the puck past a scribe and a fiber bender with the fiber extending through the hole in the planar surface of the puck; and breaking the fiber where it just extends from the planar surface of the puck by introducing a flaw in the fiber with the scribe and bending the fiber with the fiber bender.
 8. The method of claim 7, wherein the step of providing the polishing puck comprises providing the puck with a fiber lead-in groove, a nest for accommodating a fiber holder, and a hinged top.
 9. The method of claim 8, wherein the step of retaining the optical fiber comprises placing the fiber holder in the nest of the puck, placing an end of the optical fiber in the lead-in groove and through the fiber holder and hole in the planar surface of the puck, and closing the top of the puck over the optical fiber and fiber holder.
 10. The method of claim 7, wherein the step of guiding the puck comprises:providing a station base with an open groove having guide tracks on each side of the groove near the top of the station base with the scribe and fiber bender extending from a wall of the groove; and sliding the planar surface of the puck in the guide tracks of the groove.
 11. The method of claim 7, further comprising the steps of:providing a fiber end-face polishing surface; and moving the planar surface of the puck over the polishing surface with the end-face of the extending broken fiber in contact with the polishing surface.
 12. The method of claim 7, further comprising the step of viewing the end-face of the broken optical fiber with a microscope.
 13. The method of claim 11, further comprising the steps of:providing a station base with an open groove having guide tracks on each side of the groove near the top of the station base with the scribe and fiber bender extending from a wall of the groove; sliding the planar surface of the puck in the guide tracks of the groove; and providing the polishing surface on the top of the station base adjacent the open groove.
 14. The method of claim 10, wherein the step of providing the polishing puck comprises providing the puck releasably attachable to the station base.
 15. The method of claim 9, further comprising the step of opening the polishing puck to remove the optical fiber therefrom. 